JP2007086829A - Radio communication system and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To surely conduct communication for read/write by avoiding interference between electromagnetic waves reaching directly from an antenna and electromagnetic waves produced by reflection at a reflector. <P>SOLUTION: A radio communication system has a main antenna 2 which radiates electromagnetic waves toward a radio IC chip 3; a reflector 4 for reflecting the electromagnetic waves from the main antenna 2 toward the radio IC chip; and a control unit 8 supporting the radio IC chip. The control unit 8 causes a difference in the level of received electromagnetic waves between the direct wave 6 from the main antenna 2 that the antenna of the radio chip receives and the reflected waves 7a, 7b from the reflector 4. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a wireless communication system and method for performing read / write communication between wireless IC chips attached to a plurality of articles three-dimensionally stacked on a carriage passing through a passage or a production line.

  Communication of read / write between RFID tags attached to multiple items by radiating electromagnetic waves from antennas to RFID tags attached to multiple items stacked three-dimensionally on a carriage passing through a passage or production line Wireless communication systems that perform the above have been developed.

  In this wireless communication system, various methods are employed for causing electromagnetic waves from an antenna to arrive at RFID tags of a plurality of articles stacked three-dimensionally on a carriage. The method will be described.

Patent Document 1 discloses a configuration in which an antenna that inquires into a recognition area and irradiates an electromagnetic wave and a reflecting plate are disposed at opposing positions to expand the recognition area. Patent Document 2 discloses a configuration in which a plurality of antennas are arranged in the circumferential direction around a turntable on which a wireless data carrier is mounted. Patent Document 3 discloses a configuration in which a plurality of antennas are arranged in the height direction around the product placement unit. Patent Document 4 discloses a configuration in which the space is scanned by an antenna installed in a detection-symmetric space.
JP 2005-5876 A JP 2005-4532 A JP 2004-265112 A JP 2005-193030 A

  Certainly, the wireless communication system disclosed in the above-mentioned patent document utilizes the arrangement relationship of a plurality of antennas and a reflector, and directs the electromagnetic wave directly from the antenna and the electromagnetic wave reflected by the reflector to the RFID tag of the article. It is possible to arrive effectively.

  However, when a plurality of antennas are used or when a reflector is used, electromagnetic waves coming directly from the plurality of antennas to the RFID tag and reflected according to the direction of the RFID tag antenna surface with respect to the radiation direction of the electromagnetic waves from the antenna, There is a possibility that interference of electromagnetic waves due to reflection of the plate may occur, causing a state in which both the direct wave and the reflected wave cannot be effectively incident on the RFID tag. When this phenomenon occurs, the RFID tag cannot decode the data signal transmitted by the electromagnetic wave from the antenna and cannot perform the read / write communication.

  An object of the present invention is to provide a wireless communication system and method capable of reliably performing read / write communication by avoiding interference between an electromagnetic wave directly coming from an antenna and an electromagnetic wave caused by reflection of a reflector.

To achieve the above object, a wireless communication system according to the present invention includes a main antenna that radiates electromagnetic waves toward a wireless IC chip, a reflector that reflects the electromagnetic waves from the main antenna toward the wireless IC chip, A control unit for supporting the wireless IC chip;
The control unit has a function of causing a difference in received electromagnetic wave level between a direct wave from the antenna received by the antenna of the wireless chip and a reflected wave from the reflector.

  When observing from the wireless IC chip side, there is a possibility that the direct wave from the main antenna and the reflected wave from the reflector enter the antenna of the wireless IC chip almost simultaneously or with a phase shift.

  The control unit in the present invention makes a difference between the received electromagnetic wave level of the direct wave from the antenna received by the antenna of the wireless chip and the reflected wave from the reflector. For this reason, even if the direct wave from the main antenna and the reflected wave from the reflector are incident on the antenna of the wireless IC chip, a difference occurs in the received electromagnetic wave level for receiving both electromagnetic waves. No interference occurs or interference is suppressed.

  Therefore, either one of the electromagnetic wave as a direct wave from the main antenna or the electromagnetic wave as a reflected wave from the reflecting plate enters the antenna of the wireless IC chip. Therefore, an electromagnetic wave path is always formed between the main antenna and the wireless IC chip, and data communication using the electromagnetic wave is always performed between the two.

  In order to control the received electromagnetic wave level by the control unit, the following configuration is conceivable. That is, by controlling the effective reception length of the antenna of the wireless IC chip with respect to the electromagnetic wave by the control unit, the direct wave from the main antenna and the reflected wave from the reflector received by the antenna of the wireless chip are controlled. By directly controlling the effective reception area for the electromagnetic wave of the antenna of the wireless IC chip by the control unit, the antenna from the main antenna directly receives the difference. A difference is generated between the received electromagnetic wave level of the wave and the reflected wave from the reflector.

  Furthermore, the control unit is supported by a mixture of wireless IC chips having different types of antennas, and the effective reception length and effective reception area for electromagnetic waves are controlled according to the type of antenna of the wireless IC chip. The reception electromagnetic wave level of the direct wave received from the main antenna and the reflected wave from the reflecting plate received by the antenna of the wireless chip may be different.

  The reception electromagnetic wave level at which the electromagnetic wave from the main antenna is received changes the reception effective length or the tree reception effective area at the antenna of the wireless IC chip with respect to the main antenna with respect to the direct wave from the antenna and the reflected wave from the reflector. It is possible to control.

  Therefore, the present invention changes the reception effective length or reception effective area of the radio IC chip with respect to the main antenna with respect to the direct wave from the antenna and the reflected wave from the reflection plate, and the difference in the received electromagnetic wave level. Cause it to occur.

  As described above, even if the direct wave from the main antenna and the reflected wave from the reflector are incident on the antenna of the wireless IC tag almost simultaneously or with a phase shift, the level difference generated between the received electromagnetic wave levels. As a result, the interference between the two electromagnetic waves is attenuated or suppressed.

  When changing the effective reception length or effective reception area of the radio IC chip antenna with respect to the main antenna to the direct wave from the main antenna and the reflected wave from the reflector, the control unit What is necessary is just to produce the difference of the said received electromagnetic wave level by carrying out the angular rotation of the said radio | wireless IC chip within the reception area | region of the said reflected wave.

  The electromagnetic wave radiated from the main antenna toward the antenna of the wireless IC chip is not particularly limited, but a radio wave attached to a three-dimensionally stacked article or the like by using a circularly polarized electromagnetic wave as the electromagnetic wave. Data signals can be reliably transmitted to the IC chip.

  In the above example, the case where the present invention is constructed as a wireless communication system has been described, but the present invention is not limited to this. That is, it may be constructed as a wireless communication method.

  The wireless communication method according to the present invention based on the above concept includes an electromagnetic radiation step for forming an electromagnetic wave path from the main antenna to the wireless IC chip of the electromagnetic wave radiated from the main antenna and the electromagnetic wave reflected by the reflector, and the electromagnetic wave. A level control step for causing a difference between the direct wave from the main antenna received by the antenna of the wireless chip and the received electromagnetic wave level of the reflected wave from the reflector in the reception area of the direct wave and the reflected wave. Build as a configuration that includes.

  In the level control step, the following configuration can be considered to control the received electromagnetic wave level. That is, in the level control step, by controlling the effective reception length for the electromagnetic wave of the antenna of the wireless IC chip, the direct wave from the main antenna and the reflected wave from the reflector received by the antenna of the wireless chip are controlled. It causes a difference in the received electromagnetic wave level. Alternatively, in the level control step, by controlling an effective reception area for the electromagnetic wave of the antenna of the wireless IC chip, a direct wave from the main antenna and a reflected wave from the reflector received by the antenna of the wireless chip are controlled. It causes a difference in the received electromagnetic wave level.

  Further, in the level control step, the direct wave from the antenna received by the antenna of the wireless chip is controlled by controlling the effective reception length and effective reception area for the electromagnetic wave according to the type of antenna of the wireless IC chip. A difference is generated in the received electromagnetic wave level of the reflected wave from the reflecting plate.

  According to the method of the present invention, the effective reception length or the effective reception area of the antenna of the wireless IC chip with respect to the main antenna is changed with respect to the direct wave from the antenna and the reflected wave from the reflector, so that the reception electromagnetic wave level is obtained. Make a difference.

  As described above, even if the direct wave from the main antenna and the reflected wave from the reflector are incident on the antenna of the wireless IC tag almost simultaneously or with a phase shift, the level difference generated between the received electromagnetic wave levels. As a result, the interference between the two electromagnetic waves is attenuated or suppressed.

  As described above, according to the present invention, the effective reception length or effective reception area of the antenna of the wireless IC chip with respect to the main antenna is changed with respect to the direct wave from the main antenna and the reflected wave from the reflector, Even if the direct wave from the main antenna and the reflected wave from the reflecting plate are incident on the antenna of the wireless IC tag almost simultaneously or with a phase shift in order to cause a difference in the received electromagnetic wave level, Interference due to both electromagnetic waves can be attenuated or suppressed due to the level difference generated between them, and read / write communication can be reliably performed between the main antenna and the wireless IC chip.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  The wireless communication system according to the embodiment of the present invention has, as a basic configuration, a main antenna 2 that radiates electromagnetic waves toward the wireless IC chip (3) and an electromagnetic wave from the main antenna 2 toward the wireless IC chip (3). The reflector unit 4 includes a reflection plate 4 and a control unit 8 that supports the wireless IC chip (3). The control unit 8 receives the direct wave from the main antenna 2 received by the antenna of the wireless chip (3) and the reflection. It has a function of causing a difference in the received electromagnetic wave level of the reflected wave from the plate 4.

The main main antenna 2 radiates an electromagnetic wave output from the transceiver (1) toward the wireless IC chip (3). An embodiment of the present invention will be specifically described based on an example in which an RFID tag 3 is used as a wireless IC chip and a reader / writer for managing the RFDI tag 3 is used as the transceiver. Here, the RFID tag includes an antenna, a memory, and the like. The reader / writer 3 has a function of reading information from the RFID tag 3 and writing information to the RFID tag by electromagnetic waves. The reader / writer 1 is connected to the RFID tag 3 by the main antenna 2. Data signals are transmitted and received by electromagnetic waves. These RFID tags and reader / writers are general purpose ones.
(Embodiment 1)

  Embodiment 1 of the present invention is shown in FIG. As shown in FIG. 1, articles and the like to which the RFID tag 3 is attached are stacked on the carriage 9 and collected in the management area 5. The management area 5 may be a store, a warehouse in a distribution process, or the like, or a location that passes through a store passage or a production line. In short, the management area 5 means a space that is attached to an article or the like and in which a plurality of RFID tags 3 are integrated. In FIG. 1, the article to which the RFID tag 3 is attached is not shown, and only the RFID tag 3 attached to the article on the carriage 9 is illustrated.

  The main antenna 2 of the reader / writer 1 is installed above the management area 5, for example, the ceiling of the factory, with the electromagnetic wave traveling direction 6 facing downward toward the management area 5, and the electromagnetic wave from the main antenna 2 is transmitted to the management area. 5 covers most of the area. The arrow line drawn from the main antenna 2 of the reader / writer 1 indicates the electromagnetic wave and its radiation direction. Reference numeral 6 represents an image of a direct wave electromagnetic wave (hereinafter referred to as a direct wave) radiated from the main antenna 2 toward the RFID tag 3. Reference numerals 6a and 6b indicate an electromagnetic wave as a reflected wave output from the main antenna 2 and reflected to the RFID tag 3 side by a reflection plate 4 described later.

  A computer terminal 15 is connected to the reader / writer 1, and information is exchanged between the reader / writer 1 and the computer terminal 15. The computer terminal 15 is connected to the server 17 via the network 16, information from the computer terminal 15 is accumulated in the server 17, and information is output from the server 17 to the computer terminal 15 through the network 16. The server 17 creates a database of information input from the reader / writer 1 and holds the information for use in merchandise management at a store, manufacturing management at a factory, and the like.

  The plurality of reflectors 4 reflect the electromagnetic waves from the main antenna 2 of the reader / writer 1 and advance toward the RFID tag 3 in the management area 5. A reflective surface 4a is formed by applying a reflective agent, and the reflective surface 4a is configured to reflect electromagnetic waves. In the embodiment shown in FIG. 1, the reflecting plates 4 are arranged in two vertical stages in the vertical direction. In addition, the number of installation stages of the reflection plate 4 is not limited to two. The number of installation stages of the reflecting plate 4 varies depending on the stacking height of the RFID tags 3 stacked on the carriage 9. For example, when the width of the reflection plate 4 is narrow, the number of installation stages of the reflection plate 4 increases, and when the stacking height of the RFID tags 3 stacked on the carriage 9 is high, the number of installation stages of the reflection plate 4. Will be more.

  The plurality of reflecting plates 4 are installed in a plurality of stages while the reflecting surface 4a is held in an inclined posture. The inclination angle of the reflecting surface 4a is such that the electromagnetic waves 6a and 6b radiated from the main antenna 2 in the direction of the reflecting plates 4 are reflected in the substantially horizontal direction by the reflecting surface 4a, and the electromagnetic waves 7a and 7b of the reflected waves are reflected in the management region. 5 is set to an angle at which electromagnetic waves (hereinafter referred to as reflected waves) 7a and 7b of reflected waves travel toward the RFID tag 3 that is three-dimensionally stacked within the antenna 5.

The inclination angle of the reflection plate 4 is changed according to the position where the electromagnetic wave from the main antenna 2 is incident. In the illustrated example, reducing the inclination angle of the reflecting plate 4 for reflecting the electromagnetic wave 7a toward the RFIF tag 3 ₁ located in the upper part, the reflection plate for reflecting the electromagnetic wave 7b toward RFIF3 ₂ located in the lower part The inclination angle 4 is set large. The inclination angle of the reflecting plate 4 is an example, and these may be appropriately selected according to statistics of the antenna direction of the RFID tag 3 integrated in the management area 5 or according to an empirical rule. In short, all the electromagnetic waves from the main antenna 2 of the reader / writer 1 are accumulated in the accumulation space S regardless of the direction of the antenna of the RFID tag 3 by using the reflection plate 4 having the reflection surface 4a. It is only necessary that the configuration be able to reach the antenna of the RFID tag 3. When the width of the reflecting surface 4a is the same as the wavelength of the electromagnetic wave, or the length of 3/4 or 1/2 of the wavelength, the resonance phenomenon of the electromagnetic wave is caused on the reflecting surface 4a to attenuate the reflected wave. The electric power of 7a, 7b will fall. Therefore, the width of the reflector 4 is set to be equal to or greater than the wavelength of the electromagnetic wave.

  The reflecting surface 4a of the reflecting plate 4 is formed in a shape such as a planar shape, a secondary paraboloid, a cylindrical surface, or an ellipsoid. If the shape of the reflective surface 4a is a secondary parabolic surface, a cylindrical surface, an elliptical surface, or the like, the diffusion of reflected waves from the reflective surface 4a can be minimized as compared with the planar reflective surface 4a. it can. Furthermore, if the reflective surface 4a is a secondary radiation surface recessed inward, the reflected wave exhibits parallel radiation characteristics. If the reflective surface 4a is a cylindrical surface or an elliptical surface that is recessed inward, the radiation characteristic that the reflected wave converges is exhibited. In some cases, the shape of the reflecting surface 4a may be a secondary paraboloid, a cylindrical surface, an elliptical surface, or the like protruding outward.

  Here, the relationship between the reader / writer 1 and the RFID tag 3 will be described. It is assumed that the electromagnetic waves 6a and 6b output from the main main antenna 2 of the reader / writer 1 are radiated with a substantially fan-shaped directivity characteristic. In this case, depending on the positional relationship between the electromagnetic waves 6a and 6b and the antenna of the RFID tag 3, the antenna of the RFID tag 3 may not be able to receive the electromagnetic wave.

Specifically, in FIG. 1, the RFID tag 3 has a direct wave 6 from the main antenna 2 because its antenna is oriented to receive an electromagnetic wave from the main antenna 2 of the reader / writer 1. Can be received. On the other hand, the RFID tags 3 ₁ and 3 ₂ have an attitude in which the antenna is parallel to the traveling direction of the electromagnetic wave from the main antenna 2 of the reader / writer 1 or the electromagnetic wave is shielded by the RFID tag body. The direct wave 6 from the main antenna 2 of the reader / writer 1 cannot be satisfactorily received by the antenna, or the reception level is lowered.

Therefore, in the embodiment of the present invention, when information is transmitted and received between the RFID tag 3 and the reader / writer 1, electromagnetic waves 6a and 6b radiated from the main antenna 2 toward the reflecting plates 4 are reflected on the reflecting surface 4a. Reflected in a substantially horizontal direction, the reflected waves 7 a and 7 b are advanced toward the RFID tags 3 ₁ and 3 ₂ that are three-dimensionally stacked in the management area 5.

  The control unit 8 has a function of causing a difference between the received electromagnetic wave levels of the direct wave 6 from the main antenna 2 received by the antenna of the supported RFID tag 3 and the reflected waves 7 a and 7 b from the reflector 4. .

  As an antenna provided in the RFID tag 3, an antenna having a general structure such as a planar antenna, a dipole antenna, a monopole antenna, or a turn style antenna is used. The turn style antenna is an antenna in which two sets of dipole antennas are combined with each other in a positional relationship of 90 degrees. In the embodiment of the present invention, circular polarization is used for communication from the main antenna 2 to the antenna of the RFID tag 3, and the antenna of the RFID tag 3 performs both right turn and left turn when receiving electromagnetic waves. It is possible to receive a circularly polarized electromagnetic wave.

  When the antenna of the RFID tag 3 is a dipole antenna, a monopole antenna, or a turn style antenna, electromagnetic waves can be received from the front and back surfaces and the side surfaces of the RFID tag 3. When the antenna of the RFID tag 3 is a planar antenna, electromagnetic waves from the front and back surfaces of the RFID tag 3 can be received. In the case of a planar antenna, the received electromagnetic wave level changes depending on the size of the effective reception area for the electromagnetic wave radiated from the main antenna 2. In the case of a dipole antenna, a monopole antenna, and a turn style antenna, the received electromagnetic wave level changes depending on the size of the effective reception area for the electromagnetic wave radiated from the main antenna 2.

  In addition, although the dipole antenna, the monopole antenna, and the turn-style antenna are given as examples of the antenna in which the change in the received electromagnetic wave level with respect to the electromagnetic wave radiated from the main antenna 2 is caused by the change in the effective reception length, it is limited to this. is not. Further, although the planar antenna is exemplified as the antenna in which the change in the received electromagnetic wave level with respect to the electromagnetic wave radiated from the main antenna 2 is caused by the change in the effective reception length, it is not limited to this. The planar antenna includes a slot antenna, a patch antenna, a spiral antenna, and the like.

  Therefore, when the antenna of the RFID tag 3 is a dipole antenna, a monopole antenna, a turn style antenna, or the like, the control unit 8 controls the effective reception length for the electromagnetic wave of the RFID tag 3 antenna. Then, a difference is caused between the received electromagnetic wave levels of the direct wave 6 from the main antenna 2 and the reflected waves 7a and 7b from the reflector 4 received by the antenna of the RFID tag 3. When the antenna of the RFID tag 3 is a planar antenna or the like, the control unit 8 controls the effective reception area of the antenna of the RFID tag 3 with respect to the electromagnetic wave, thereby receiving the main antenna 2 received by the antenna of the RFID tag 3. A difference is generated between the received electromagnetic wave levels of the direct wave 6 from the reflector 6 and the reflected waves 7a and 7b from the reflector 4.

  Furthermore, when the RFID tag 3 includes a dipole antenna, a monopole antenna, a turn style antenna, a planar antenna, etc., the effective reception length and effective reception area for electromagnetic waves are controlled according to the type of the RFID tag 3 antenna. As a result, the received electromagnetic wave level of the direct wave 6 from the main antenna 2 received by the antenna of the RFID 3 and the reflected waves 7a and 7b from the reflecting plate 4 is made different.

  In the embodiment, the control unit 8 is constituted by a carriage 9 used for conveying articles and the like. This will be specifically described. As shown in FIG. 1, a cart 9 constituting the control unit 8 includes a vehicle body 9 a that loads and moves an article, a top plate 9 b that supports the article, and a power source 10 for rotational driving.

  The top plate 9b is supported on the top of the vehicle body 9a so as to be capable of angular rotation about a rotation shaft 9c, and an article with the RFID tag 3 attached thereto is three-dimensionally loaded on the top plate 9b. . The drive source 10 has an output shaft 10a connected to a rotating shaft 9c of the top plate 9b. The drive source 10 is controlled based on a command from the server 17 and rotates the top plate 9b by an angle.

  When the vehicle body 9a enters the management area 5, the driving source 10 controls the effective reception length and effective reception area for the electromagnetic wave of the antenna of the RFID tag 3 by rotating the top plate 9b. A difference is caused between the received electromagnetic wave levels of the direct wave 6 from the main antenna 3 and the reflected waves 7a and 7b from the reflector 4a received by the antenna.

  Next, the operation of the wireless communication system according to the embodiment of the present invention will be described. The RFID tag 3 is attached to an item to be identified. The RFID tag 3 is written with information necessary for identifying an article using an information writing device (not shown). The RFID tag 3 in which information is written in this way is carried in the accumulation space S along with the article, and a plurality of RFID tags 3 are accumulated in the space S.

  The article attached with the RFID tag 3 is stacked on the carriage vertically and is carried to the management area 5 in the accumulation space S. In the process in which the article is carried into the management area 5, the direction of the antenna of the RFID tag 3 is changed. There is no management, and the direction of the antenna is in a random direction.

  In the management area 5 in which a plurality of RFID tags 3 are integrated, an electromagnetic wave from the main antenna 2 of the reader / writer 1 installed on the ceiling of the management area 5 is radiated, for example, in time with the carry-in of an article. Based on the above, the reader / writer reads the information of the RFID tag 3 to manage the article.

  However, as described above, since the antenna of the RFID tag 3 faces a random direction, electromagnetic waves radiated from the main antenna 2 of one reader / writer 1 are transmitted to the antenna of the RFID tag 3 facing a random direction. It is impossible to receive.

  When a cart 9 enters a management area 5 in which a plurality of reflectors 4 are arranged in a plurality of stages above and below, in addition to the electromagnetic wave path from which the electromagnetic waves directly arrive at the antenna of the RFID tag 3 from the main antenna 2, the reflector 4 A path of electromagnetic waves arriving at the RFID tag 3 from the main antenna 2 through the reflection surface 4a is formed.

  Therefore, the direct wave 6 from the reader / writer 1 directly reaches the RFID tag 3 that is receiving the electromagnetic wave radiated from the main antenna 2 of the reader / writer 1, and the antenna of the RFID tag 3 and the reader / writer 1 Two-way communication using electromagnetic waves is performed using the main antenna 2. Thereby, the information written in the RFID tag 3 is collected by the reader light 1 and sent to the computer terminal 15. The computer terminal 15 provides the information obtained from the reader / writer 1 to the server 17 through the network 16. Based on the information provided from the computer terminal 15, the server 17 manages an article to which the RFID tag 3 is attached. The server 17 sends the information to the computer terminal 15 through the network 16 when the article management information is changed or when it is necessary to add new information.

  When receiving information from the server 17, the computer terminal 15 sends the information to the reader / writer 1. The reader / writer 1 radiates the received information from the main antenna 2 toward the space S by electromagnetic waves. When the corresponding RFID tag 3 directly receives information from the reader / writer 1 from the main antenna 2, the information is written in the memory of the corresponding RFID tag 3.

When the antenna of the RFID tag 3 is not in a receiving state with respect to electromagnetic waves from the main antenna 2 of the reader / writer 1, as shown in FIG. 1, these RFID tags 3 ₁ and 3 ₂ have a reflector 4 Electromagnetic waves (reflected waves 7a and 7b) from the main antenna 2 of the reader / writer 1 arrive by the reflecting surface 4a.

Surely, the reflected waves 7a and 7b reflected by the reflector 4 arrive at the RFID tags 3 ₁ and 3 ₂ located in a region where the direct wave 6 from the main antenna 2 does not reach. 3, the direct wave 6 from the main antenna 2 and the reflected waves 7 a and 7 b from the reflecting plate 4 may be incident.

  As described above, the direct wave 6 that directly arrives at the RFID tag 3 from the main antenna 2 and the reflected wave 7a reflected by the reflection plate 4 according to the direction of the RFID tag antenna with respect to the radiation direction of the electromagnetic wave from the main antenna 2 are reflected. 7b is incident, and there is a risk of interference between the direct wave 6 and the reflected waves 7a and 7b, and both the direct wave and the reflected wave are effectively incident on the RFID tag. An impossible state is caused. When this phenomenon occurs, the RFID tag cannot decode the data signal transmitted by the electromagnetic wave from the antenna and cannot perform the read / write communication.

  Therefore, the control unit 8 makes a difference between the received electromagnetic wave levels of the direct wave 6 from the main antenna 2 received by the antenna of the RFID tag 3 and the reflected waves 7a and 7b from the reflection plate 4.

  More specifically, in the plurality of RFID tags 3 attached to the article, the antenna of each RFID tag faces a random direction. Therefore, when the RFID tag 3 is angularly rotated in the management area 5, when the antenna of the RFID tag 3 is a planar antenna, the planar antenna reception effective area with respect to the radiation directions of the direct wave 6 and the reflected waves 7a and 7b changes. The received electromagnetic wave levels of the direct wave and the reflected wave also change. When the antenna of the RFID tag is a dipole antenna or a monopole antenna, the effective reception lengths of the RFID antenna with respect to the radiation directions of the direct wave 6 and the reflected waves 7a and 7b change, and the direct wave 6 and the reflected waves 7a and 7b The received electromagnetic wave level changes.

  When a difference occurs in the reception electromagnetic wave level with respect to the direct wave 6 and the reflected waves 7a and 7b of the antenna of the RFID tag 3, interference between electromagnetic waves is reduced. When the difference between the received electromagnetic wave levels with respect to the direct wave 6 and the reflected waves 7a and 7b is maximized, either the direct wave 6 or the reflected waves 7a and 7b is effectively incident on the antenna of the RFID tag 3. .

  As described above, when the interference between electromagnetic waves received by the antenna of the RFID tag 3 is reduced, or when one of the direct wave 6 and the reflected waves 7a and 7b is effectively incident on the antenna of the RFID tag 3, the RFID Data can be demodulated on the tag 3 side.

Next, the difference between the effective reception length, the effective reception area, and the reception electromagnetic wave level for the electromagnetic wave from the main antenna 2 of the antenna of the RFID tag 3 will be described with reference to FIG. Figure 2 is a direct wave 6 from the main antenna 2, the reflected waves 7c from the reflecting plate 4, 7d indicates an incident ready to antenna of the RFID tag 3 _1. In Figure 2 has been described only for the RFID tag _{3 1} in FIG. 1 is the same for the RFID tag _{3 2.}

As shown in FIG. 2, the electromagnetic wave 6,6c from the main antenna 2, 6d is the RFID tag _{3 1} attached to an article that is stacked on the vehicle body 9a, directly from the main antenna 2 as a wave 6 directly or, The reflected light is radiated as reflected waves 7c and 7d from the substantially horizontal direction by the reflecting plate 4.

Electromagnetic wave level RFID tag 3 _first antenna receives the reflected wave and the path length of the electromagnetic wave from the main antenna 2 to the RFID tag 3 _first antenna, from a radiation direction or the reflection plate 4 of the direct wave 6 from the main antenna 2 the relative radial changes the reception effective length or reception effective area of the RFID tag 3 _first antenna. Reception effective length or reception effective area of the RFID tag 3 ₁ changes due to the orientation of the RFID tag 3 _first antenna directly to radiant direction of the reflected wave from the radial or reflection plate 4 of the wave 6 from the main antenna 2 To do. Monopole antenna, a dipole antenna, a turnstile antenna, receiving effective length the length of the RFID tag 3 _first antenna viewed from the radiation direction of the electromagnetic wave from the main antenna 2 side, in the planar antenna, the electromagnetic wave from the main antenna 2 side the area of the antenna surface of the RFID tag 3 ₁ viewed from the radial direction to receive effective area. In this case, when the normal to the antenna surface of the RFID tag 3 ₁ said radial reception effective length or reception effective area is maximized, the receiving electromagnetic wave level indicates the maximum value.

In the example shown in FIG. 2, the path of the direct wave 6 to _one RFID tag 31 and the path of the reflected waves 7c and 7d via one reflector 4 that is substantially horizontal to the RFID tag 3 are formed. are, antenna surface of the RFID tag 3 ₁ faces in a state inclined by 45 degrees with respect to the longitudinal direction of the reflecting surface 4a of the reflector 4.

(In the case of a flat antenna before adjusting the reception electromagnetic wave level)
In FIG. 2, the RFID tag _{3 first} antenna is a plane antenna, facing at about 45 degrees with respect to the antenna surface is direct wave 6 of the planar antenna in the RFID tag _{3 1,} the reflecting surface 4a is direct wave 6c of the reflector 4 , 6d facing each other at approximately 45 degrees, and the antenna surface of the planar antenna faces the reflected waves 7c, 7d from the reflecting plate 4 at approximately 45 degrees.

The reception effective area of a square whose one side of the antenna surface of the planar antenna is A cm is A ² cm ² , and when it is tilted 45 degrees, the reception effective area changes to A ² / √2 cm ² , so that the plane in FIG. The effective reception area of the antenna is 1 / √2 (; 0.7). In this case, including the direct wave 6 and the reflected waves 7c, when comparing the route to the RFID tag 3 _first planar antenna 7d, than the path of the direct wave 6, the reflected wave via the reflection plate 4 (direct wave 6c, and 6d ) The routes 7c and 7d are only slightly longer. Therefore, there is almost no difference in the received electromagnetic wave level from the direct wave 6 and the reflected waves 7c and 7d.

In contrast, (including direct wave 6c, a 6d) when considered in terms of the electromagnetic wave mutual phase received by the RFID tag 3 ₁ of a planar antenna, and the path of the direct wave 6, the reflected wave via the reflection plate 4 7c , 7d have a slight difference in the length of the path, so that a phase shift occurs between the direct wave 6 incident on the RFID tag surface and the reflected waves 7c, 7d.

Describing using numerical values, if the frequency of the electromagnetic wave is 2 GHz, one wavelength is 15 cm, the path of the direct wave 6, and the reflected waves (including the direct waves 6c and 6d) 7c and 7d via the reflector 4 Although the path length difference is somewhat when considered in terms of phase, RFID tag 3 ₁ of the direct wave 6 is incident on the antenna surface reflected waves 7c, the phase shift between 7d mutual occur.

Therefore, since the direct wave 6 and the reflected waves 7c of the flat antenna in the RFID tag 3 _1, little difference no in the reception wave level for 7d, the direct wave 6 and the reflected waves 7c, the phase shift between 7d mutual occur, directly Interference occurs between the wave 6 and the reflected waves 7c and 7d. Therefore, can not demodulate data signals RFID tag 3 ₁ from the received electromagnetic wave, view can decode the inquiry signal from the main antenna 2, the RFID tag 3 ₁ not return a response signal is not performed communication with the main antenna 2.

(In case of monopole antenna and dipole antenna before adjustment of received electromagnetic wave level)
Next, a description will be given of a case where the RFID tag 3 _first antenna is a monopole antenna, a dipole antenna in FIG. FIG. 3 is a cross-sectional view taken along line ab in FIG.

When RFID tag 3 _first antenna is a monopole antenna, a dipole antenna, as shown in FIG. 3, a monopole antenna, when a dipole antenna is in a vertical state 13, the direct wave 6 reflected waves 7c, substantially each 7d 45 The effective reception lengths of these antennas for the direct wave 6 and the reflected waves 7c and 7d are 1 / √2 (; 0.7).

  As shown in FIG. 3, when the monopole antenna and the dipole antenna are in the horizontal state 14, the direct wave 6 and the reflected waves 7c and 7d face each other at an angle of about 90 degrees, and the direct wave 6 and the reflected wave of these antennas are reflected. The effective reception length for the waves 7c and 7d is the full length (; 1).

As described above, even in orientation which state of the RFID tag 3 _first antenna, the RFID tag 3 _first antenna of the direct wave 6 and the reflected waves 7c, while little difference in the reception wave level for 7d is there.

In contrast, (including direct wave 6c, a 6d) when considered in terms of the electromagnetic wave mutual phase received by the RFID tag 3 _first antenna, and the path of the direct wave 6, the reflected wave via the reflection plate 4 7c, for the 7d path length there is a slight difference, RFID tag 3 ₁ of the direct wave 6 is incident on the antenna surface reflected waves 7c, the phase shift between 7d mutual occur.

  Describing using numerical values, if the frequency of the electromagnetic wave is 2 GHz, one wavelength is 15 cm, the path of the direct wave 6, and the reflected waves (including the direct waves 6c and 6d) 7c and 7d via the reflector 4 The difference in path length is slight, but considering the phase, there is a phase shift between the direct wave 6 incident on the RFID tag surface and the reflected waves 7c and 7d.

Therefore, since the direct wave 6 and the reflected waves 7c of the flat antenna in the RFID tag 3 _1, little difference no in the reception wave level for 7d, the direct wave 6 and the reflected waves 7c, the phase shift between 7d mutual occur, directly Interference occurs between the wave 6 and the reflected waves 7c and 7d. Therefore, can not demodulate data signals RFID tag 3 ₁ from the received electromagnetic wave, can not decode the inquiry signal from the main antenna 2, the RFID tag 3 ₁ not return a response signal is not performed communication with the main antenna 2.

Therefore, in the embodiment of the present invention, the control unit 8 causes a difference in the received electromagnetic wave level. Specifically, the top plate 9b of the body 9a in the management area 5 is angularly rotated by the drive source 10, the direct wave 6 and the reflected waves 7c, changes the orientation of the RFID tag 3 _first antenna for 7d. FIG. 4 shows a state in which the top plate 9b is rotated 90 degrees by the driving source 10. FIG. 5 is a cross-sectional view taken along line ab in FIG.

An inquiry signal (circularly polarized electromagnetic wave) is continuously transmitted from the main antenna 2 during the period in which the top plate 9b rotates 90 degrees. When the top plate 9b is rotated by 90 degree angle, as shown in FIG. 4, RFID tag 3 ₁ is in a state of being rotated 90 degrees clockwise rotation from the state of FIG.

(In the case of a flat antenna after adjusting the received electromagnetic wave level)
There is almost no change in the reception effective area for the direct wave 6 of the planar antenna, and the reception effective area is 1 / √2 (; 0.7). In contrast, the orientation of the antenna surface of the RFID tag _{3 1} becomes parallel to the radial direction of the reflected waves 7c, 7d, the reception effective area with respect to the reflected waves 7 is hardly (; 0).

As described above, by the operation of the control unit 8, for receiving electromagnetic wave level difference with respect to the reflected waves 7c, 7d and the direct wave 6 of the planar antenna in the RFID tag 3 ₁ occurs, and the reflected wave waves 6 directly at the antenna surface of the flat antenna Even if a phase shift occurs between 7c and 7d, interference between electromagnetic waves between the direct wave 6 and the reflected waves 7c and 7d is reduced. Therefore, RFID tag _{3 1} can demodulate data signals from the direct wave 6. By rotating the direction of the antenna at least 90 degrees, the data signal can be demodulated from the received electromagnetic wave, and the inquiry signal from the main antenna 2 can be decoded.

(In case of monopole antenna and dipole antenna after receiving electromagnetic wave level adjustment)
RFID tag 3 _first antenna monopole antenna, when a dipole antenna, as shown in FIG. 5, a monopole antenna, when a dipole antenna is in a horizontal state 14, the direct wave 6 facing at an angle of approximately 90 degrees The effective reception length is the full length (; 1). However, it becomes parallel to the radiation direction of the reflected waves 7c and 7d, and its effective reception length disappears (; 0). When the antenna is in the vertical state 13, it faces the direct wave 6 at an angle of approximately 45 degrees, and its reception effective length is 1 / √2 (; 0.7). However, it faces the reflected wave 7 at an angle of approximately 90 degrees, and its effective reception length is the full length (; 1).

In either state, there is a difference in the received electromagnetic wave level between the direct wave 6 and the reflected wave 7. Therefore, even if a phase shift occurs between the direct wave 6 and the reflected waves 7 c and 7 d on the antenna surface of the RFID tag 3, the electromagnetic wave interference between reduces, RFID tag 3 ₁ can demodulate the data signal from the direct wave 6 or the reflected wave 7. By rotating at least 90 degrees, the data signal can be demodulated from the received electromagnetic wave, and the inquiry signal from the main antenna 2 can be decoded.

The above results are shown in the table of FIG. FIG. 10 shows the effective reception area or effective reception length of each antenna in the state of FIGS. The turn-style antenna is a combination of a horizontal state and a vertical state of a dipole antenna, and the total value of both is represented as a reception effective length. Even when a turn-style antenna is used as the antenna of the RFID tag 3, the interference of electromagnetic waves can be determined based on the effective reception length. In the state of FIG. 3, the effective reception length is the same value (1.7). can not demodulate the data signal from the electromagnetic wave, the orientation of the RFID tag 3 _first antenna rotates clockwise 90 degrees, a difference occurs in the reception effective length, it becomes possible to demodulate the data signal.

During the period in which the top plate 9b of the vehicle body 9a is angularly rotated, the main antenna 2 to a plurality of RFID tags 3 ₁ piled stereoscopically on the vehicle body 9, repeatedly inquiry signals (electromagnetic waves) by calling Then, it communicates with each RFID tag 3 that has responded. Computer terminal 15 stores the RFID tag 3 ₁ identification number communicating a response is completed, respectively.

Rate to the angular rotation of the top plate 9b of the body 9a decodes the interrogation signal RFID tag _{3 1} direct wave 6 or the reflected waves 7c, from 7d, the RFID tag _{3 1} toward a response signal to the main antenna 2 with respect thereto The speed is set so that a series of communication is possible until the communication is terminated after several transmissions between the RFID tag 3 and the main antenna 2 are performed after the transmission.

As shown in FIGS. 2 to 5, by rotating at least 90 degrees RFID tag _{3 1,} effective utilizing main antenna 2 and the RFID tag 3 between the direct wave 6 or reflected waves 7c, 7d during angular rotation is the communication path is formed, the RFID tag 3 ₁ originates toward the response signal to the main antenna 2, further communication several times to the communication between the RFID tag 3 ₁ and the main antenna 2 is terminated.

The posture of the RFID tag _{3 1} shown in FIG. 6, the RFID tag _{3 first} antenna surface is parallel to the radial direction of the direct wave 6 and the RFID tag _{3 1} and the reflected wave from the reflecting plate 4 that is substantially horizontally 7c and 7d are also parallel to the radiation direction. FIG. 7 is a cross-sectional view taken along the line ab of FIG. In Figure 6, have been described only for the RFID tag _{3 1} in FIG. 1 is the same for the RFID tag _{3 2.}

(In the case of a flat antenna before adjusting the reception electromagnetic wave level)
If using a planar antenna in the RFID tag 3 _first antenna, the antenna plane is the direct wave 6 reflected waves 7c of the planar antenna, 7d in a substantially parallel, not each receive effective area (; 0). Therefore, RFID tag ₃ lower receiving electromagnetic wave level by the _first antenna, RFID tag _{3 1,} as described above can not demodulate the data signal from the received electromagnetic wave.

(In case of monopole antenna and dipole antenna before adjustment of received electromagnetic wave level)
Monopole antenna, a dipole antenna when in use in the RFID tag 3 _first antenna, when the antenna is in a horizontal state 14, directly receives the effective length of the wave 6 is full length (; 1), and the reflected waves 7c, for 7d The effective reception length disappears (0). When the antenna is in the vertical state 13, there is no effective reception length for the direct wave 6 (0), and the effective reception length for the reflected waves 7c and 7d is the full length (; 1). Both conditions, there is a difference in the reception electromagnetic wave level of the reflected wave and direct wave, RFID tag 3 _1, as described above can be demodulated data signal from the received electromagnetic wave.

RFID tag 3 ₁ on the vehicle body 9a is continued angular rotation, and is also the inquiry signal is also repeatedly originating from the main antenna 2. 8, from the state of FIG. 6 in the state in which the RFID tag _{3 1} is rotated 90 degrees clockwise, the RFID tag _{3 1} and the path of the direct wave 6 to a reflector 4 reflecting wave that has passed through the (direct wave 6c, 7c and 7d) (including 6d). FIG. 9 is a cross-sectional view taken along line ab in FIG.

(In the case of a flat antenna after adjusting the received electromagnetic wave level)
If using a planar antenna in the RFID tag 3 _first antenna, the antenna surface of the RFID tag 3 ₁ is parallel to the radial direction of the direct wave 6, also receives effective area in the state shown in FIG. 6 is not (; 0). However, RFID tag _{3 first} antenna surface reflected wave 7c, facing perpendicular to the radial direction of 7d, the reception effective area with respect to the reflected waves 7c, 7d becomes entirely (; 1). RFID tag _{3 1} can demodulate the data signal from the reflected wave 7c, 7d. By rotating at least 90 degrees, so that the RFID tag 3 ₁ can demodulate the data signal from the received electromagnetic wave.

(In the case of monopole antenna and dipole antenna after receiving electromagnetic wave level adjustment)
When using a monopole antenna, a dipole antenna in the RFID tag 3 _first antenna, when the antenna is in a horizontal state 14, the direct wave 6 facing at an angle of also approximately 90 degrees in the state of FIG. 6, the reception effective length Is the full length (; 1). However, they face each other at an angle of 90 degrees with respect to the radiation directions of the reflected waves 7c and 7d, and the effective reception length is the full length (; 1).

When the antenna is in the vertical state 13, there is no effective reception length of the direct wave 6 (; 0) as in the state of FIG. 6, and the effective reception length of the reflected wave 7 is the full length (; 1). By rotating at least 90 degrees, when the antenna is in a horizontal state 14, the direct wave 6 and the reflected waves 7c, receiving electromagnetic wave level of 7d are equal, but the RFID tag 3 ₁ no longer be demodulated data signal from the received electromagnetic wave When the antenna is in the vertical state 13, there is no change.

  FIG. 11 is a table showing the effective reception area or effective reception length of each antenna in the states of FIGS. 6 and 8 described above. In the state of FIG. 6, the turn style antenna has the same effective reception length (; 1), and the data signal cannot be demodulated from the received electromagnetic wave. However, if the turn style antenna is rotated 90 degrees, a difference occurs in the effective reception length and the data signal can be demodulated. It becomes like this.

The top plate 9b is during angular rotation of the vehicle body 9a, the main antenna 2 to a plurality of RFID tags 3 ₁ piled stereoscopically on the vehicle body 9a, transmits repeatedly inquiry signals, respectively that respond It communicates with the RFID tag _{3 1.} Computer terminal 15 has a response, and stores the RFID tag 3 ₁ identification number has finished communication, respectively. Angular rotation speed of the top plate 9b decodes the interrogation signal RFID tag _{3 1} direct wave 6 or the reflected waves 7c, from 7d, whereas transmits towards the RFID tag _{3 1} response signal to the main antenna 2, subsequent until the end of the communication several times to the communication between the RFID tag 3 ₁ and the main antenna 2 is set to a speed which can range communications.

From Figure 6, as shown in FIG. 9, by rotating at least 90 degrees RFID tag 3 _1, valid communication path using the main antenna 2 directly between the RFID tag 3 wave 6 or reflected waves 7 during rotation is formed, the RFID tag 3 ₁ originates toward the response signal to the main antenna 2, further communication several times to the communication between the RFID tag 3 ₁ and the main antenna 2 is terminated.

Other examples of the direction of the antenna shown in FIGS. 2 to 9, facing perpendicular to the radial direction of the RFID tag 3 ₁ of the antenna surface is direct wave 6, receiving the effective area at angular rotation is always the direct wave 6 is entirely (; 1) or the effective reception length may be the full length (; 1). In this case, during the rotation of the RFID tag 3 ₁ of 90 degrees, the effective area or reception effective length received by the reflected waves 7 it becomes 1 or less, so that the RFID tag 3 ₁ can demodulate the data signal from the received electromagnetic wave.

By rotating at least 90 degrees, a difference in the reception electromagnetic wave level of the direct wave 6 of the RFID tag 3 ₁ which is sterically stacked on the dolly 9 reflected wave 7 is generated during rotation, it becomes possible to demodulate the data signal . Computer terminal 15 determines that communicates with all the RFID tags 3 ₁ on the dolly 9, stopping the sending of the interrogation signal. At the same time, the rotation of the turntable 10 or 12 is stopped, and the carriage starts to advance in the passage and the production line 5.

When the carriage travels along the passage and the production line and comes to the end of the quadrangular reflecting plate 4 installed on the side or both sides, the top plate 9b of the vehicle body 9a may start rotating. At the same time, while the carriage 9 for starting the transmission of the inquiry signal from the upper main antenna 2 passes the side of the reflector 4, the main antenna 2 repeatedly transmits the inquiry signal, and each RFID tag 3 that has responded. ₁ to communicate. Computer terminal 15 has a response, and stores the RFID tag 3 ₁ identification number has finished communication, respectively.

(Embodiment 2)
FIG. 12 is a configuration diagram showing a radio communication system according to Embodiment 2 of the present invention. In the embodiment of the present invention, the reflecting plate 4 shown in FIG. That is, a plurality of reflecting plates 4 are made into two sets, and each reflecting plate 4 is mounted on both opposite wall surfaces of a shop or a factory, or on both sides of a shop passage or a factory production line, using metal fittings or the like. It is arranged so as to surround the attachment and management area 5. Alternatively, the plurality of reflecting plates 4 are suspended from the metal fittings or the like on both sides substantially vertically by a string or the like. The plurality of reflectors 4 on both wall surfaces or both sides are attached to be inclined so as to reflect the electromagnetic waves 6a and 6b from the main antenna 2 and radiate the reflected waves 7a and 7b horizontally or substantially horizontally. The three-dimensionally stacked RFID tags 3 emit electromagnetic waves 6 directly from the main antenna 2 from above, and the RFID tags 3 ₁ and 3 ₂ have reflected waves from the reflectors 4 arranged horizontally on both sides, respectively. 7a and 7b are emitted.

According to the embodiment of the present invention, the reflected waves 7a and 7b reflected by the reflecting surface 4a of the reflecting plate 4 from a plurality of directions with respect to the RFID tags 3 ₁ and 3 ₂ mounted three-dimensionally on the vehicle body 9a. Since it travels, the reflected waves 7a and 7b can be reliably irradiated to the RFID tags 3 ₁ and 3 ₂ . Furthermore, communication with a wide range of RFID tags 3, 3 ₁ , 3 ₂ and communication at a low electromagnetic wave level can be performed by the reflected waves 7 a, 7 b from one of the reflection plates 4. When the management area 5 is formed in a store passage or a part of a factory production line, when the vehicle body 9a arrives below the main antenna 2, it is attached to the article on the top board 9b and the article. The obtained RFID tags 3, 3 ₁ and 3 ₂ are angularly rotated to suppress interference between electromagnetic waves between the direct wave 6 and the reflected waves 7a and 7b on the antenna surface of the RFID tag.

  In the RFID tag 3 in which the paths from the reflecting plates 4 on both sides are at the same position, the received electromagnetic wave levels with respect to the reflected waves from the reflecting plates 4 on both sides become equal, and interference may occur between the electromagnetic waves. However, in the embodiment of the present invention, the received electromagnetic wave level of each reflected wave 7 changes due to the antenna surface of the RFID tag being parallel to the radiation direction of the reflected waves 7a and 7b during angular rotation of at least 90 degrees. Thus, interference between electromagnetic waves can be reduced, and communication with the RFID tag 3 can be performed reliably.

In the embodiment shown in FIG. 12, the direct wave 6 from the main antenna 2 and the reflected waves 7a and 7b from the reflecting plate 4 are received by the respective RFID tags 3, 3 ₁ and 3 ₂ and the control unit 8 is used. Thus, the function of causing a difference in the received electromagnetic wave level between the direct wave 6 and the reflected waves 7a and 7b on the antenna surface of the RFID tags 3, 3 ₁ and 3 ₂ is executed in the same manner as in the first embodiment.

(Embodiment 3)
FIG. 13 is a configuration diagram showing a radio communication system according to Embodiment 3 of the present invention. In the above embodiment, the control unit 8 is constituted by the carriage 9, but in the embodiment of the present invention, the control unit 8 is constituted separately from the carriage 9.

  As shown in FIG. 13, below the management area 5, there are provided a rotating base 12 for rotating a carriage 9 and a driving source 13 for rotating the rotating base 12 at an angle, and rotating an output shaft 13 a of the driving source 13. It is connected to the base 12. A control unit 8 is constituted by the turntable 12 and the drive source 13. A plurality of reflectors 4 are attached to the side of the turntable 12 substantially vertically using metal fittings etc. with the management area 5 interposed therebetween. Alternatively, the plurality of reflectors 4 are suspended from the metal fittings or the like sideways in a substantially vertical direction by a string or the like. When the carriage 9 passing through the management area 5 is placed on the turntable 12 installed below the main antenna 2, the carriage 9, the articles stacked on the carriage 9, and the RFID tag 3 attached to the article start to rotate.

When the drive source 13 causes the turntable 12 to rotate angularly, the carriage 9 supported by the turntable 12 rotates angularly, and the main antenna 2 is stacked three-dimensionally on the carriage 9 during the period in which the carriage 9 rotates angularly. a plurality of toward the RFID tag _{3, 3} 1, _{3 2,} transmits repeatedly inquiry signals to communicate with each RFID tag 33,3 _{1, 3 2} for which the response. The computer terminal 15 has a response, and stores the identification numbers of the RFID tags 3, 3 ₁ , 3 ₂ that have finished communication. Angular rotation speed of the top plate 9b decodes the interrogation signal RFID tag _{3 1} direct wave 6 or the reflected waves 7c, from 7d, whereas the RFID tag _{3, 3} 1, _{3 2} toward a response signal to the main antenna 2 The communication speed is set to a speed at which a series of communications can be performed until the communication is terminated after several communications between the RFID tags 3, 3 ₁ , 3 ₂ and the main antenna 2.

In the embodiment shown in FIG. 12, the direct wave 6 from the main antenna 2 and the reflected waves 7a and 7b from the reflecting plate 4 are received by the respective RFID tags 3, 3 ₁ and 3 ₂ and the control unit 8 is used. Thus, the function of causing a difference in the received electromagnetic wave level between the direct wave 6 and the reflected waves 7a and 7b on the antenna surface of the RFID tags 3, 3 ₁ and 3 ₂ is executed in the same manner as in the first embodiment.

According to the embodiment of the present invention, the reflected waves 7a and 7b reflected by the reflecting surface 4a of the reflecting plate 4 from a plurality of directions with respect to the RFID tags 3 ₁ and 3 ₂ mounted three-dimensionally on the carriage 9 are displayed. Since it travels, the reflected waves 7a and 7b can be reliably irradiated to the RFID tags 3 ₁ and 3 ₂ . Further, when the management area 5 is formed in a store passage or a part of a factory production line, when the carriage 9 arrives below the main antenna 2, it is attached to the articles and articles on the carriage 9. Further, the RFID tags 3, 3 ₁ and 3 ₂ are angularly rotated to suppress interference between electromagnetic waves between the direct wave 6 and the reflected waves 7a and 7b on the antenna surface of the RFID tag.

  Further, according to the embodiment of the present invention, since the control unit 8 is configured separately from the cart 9, it is not necessary to modify the configuration of the cart 9, and the conventional cart 9 is used as it is. Can do. Further, since the control unit 8 is constructed in the basement of the management area 5, it is possible to avoid the control unit 5 from hindering the transportation of the carriage 9 on the management area 5.

(Embodiment 4)
FIG. 14 is a configuration diagram showing a radio communication system according to Embodiment 4 of the present invention. In the embodiment of the present invention, the reflector 4 shown in FIG. 13 is disposed so as to surround the management area 5. That is, a plurality of reflecting plates 4 are made into two sets, and each reflecting plate 4 is mounted on both opposite wall surfaces of a shop or a factory, or on both sides of a shop passage or a factory production line, using metal fittings or the like. It is arranged so as to surround the attachment and management area 5. Alternatively, the plurality of reflecting plates 4 are suspended from the metal fittings or the like on both sides substantially vertically by a string or the like. The plurality of reflectors 4 on both wall surfaces or both sides are attached to be inclined so as to reflect the electromagnetic waves 6a and 6b from the main antenna 2 and radiate the reflected waves 7a and 7b horizontally or substantially horizontally. The three-dimensionally stacked RFID tags 3 emit electromagnetic waves 6 directly from the main antenna 2 from above, and the RFID tags 3 ₁ and 3 ₂ have reflected waves from the reflectors 4 arranged horizontally on both sides, respectively. 7a and 7b are emitted.

According to the embodiment of the present invention, the reflected waves 7a and 7b reflected by the reflecting surface 4a of the reflecting plate 4 from a plurality of directions with respect to the RFID tags 3 ₁ and 3 ₂ mounted three-dimensionally on the carriage 9 are displayed. Since it travels, the reflected waves 7a and 7b can be reliably irradiated to the RFID tags 3 ₁ and 3 ₂ . Furthermore, communication with a wide range of RFID tags 3, 3 ₁ , 3 ₂ and communication at a low electromagnetic wave level can be performed by the reflected waves 7 a, 7 b from one of the reflection plates 4. Further, when the management area 5 is formed in a store passage or a part of a factory production line, when the carriage 9 arrives below the main antenna 2, it is attached to the articles and articles on the carriage 9. Further, the RFID tags 3, 3 ₁ and 3 ₂ are angularly rotated to suppress interference between electromagnetic waves between the direct wave 6 and the reflected waves 7a and 7b on the antenna surface of the RFID tag.

  In the RFID tag 3 in which the paths from the reflecting plates 4 on both sides are at the same position, the received electromagnetic wave levels with respect to the reflected waves from the reflecting plates 4 on both sides become equal, and interference may occur between the electromagnetic waves. However, in the embodiment of the present invention, the received electromagnetic wave level of each reflected wave 7 changes due to the antenna surface of the RFID tag being parallel to the radiation direction of the reflected waves 7a and 7b during angular rotation of at least 90 degrees. Thus, interference between electromagnetic waves can be reduced, and communication with the RFID tag 3 can be performed reliably.

In the embodiment shown in FIG. 13, the direct wave 6 from the main antenna 2 and the reflected waves 7 a and 7 b from the reflector 4 are received by the respective RFID tags 3, 3 ₁ , 3 ₂ , and the control unit 8. Thus, the function of causing a difference in the received electromagnetic wave level between the direct wave 6 and the reflected waves 7a and 7b on the antenna surface of the RFID tags 3, 3 ₁ and 3 ₂ is executed in the same manner as in the first embodiment.

  In the above embodiment, the present invention is applied to the management of articles, but the present invention is not limited to this. A wireless IC chip (for example, an RFID tag) may be attached to an article, member, or device that is moved by a belt conveyor or a carriage to manage these. In addition, a wireless IC chip (for example, an RFID tag) may be attached to an article, member, or device stored in a factory, warehouse, distribution channel, or the like to manage them. Further, the present invention may be applied to the recognition of a person or an individual or the management of entrance / exit by carrying or attaching a wireless IC chip (for example, an RFID tag) to a person or an animal.

  As described above, according to the present invention, the distance between the radio IC chip attached to a plurality of three-dimensionally stacked articles and the main antenna, and the direction of the antenna surface of the radio IC chip with respect to the radiation direction of electromagnetic waves can be determined. Regardless, interference between the direct wave and the reflected wave can be avoided, and either the direct wave or the reflected wave can be effectively incident on the antenna surface, so that wireless communication can be reliably performed.

It is a block diagram which shows the radio | wireless communications system which concerns on Embodiment 1 of this invention. In embodiment of this invention, it is a side view which shows the state which the RFID tag has faced the reflecting plate in the state inclined 45 degree | times upwards. It is sectional drawing which follows the ab line | wire of FIG. FIG. 3 is a side view showing a state where the RFID tag is rotated 90 degrees clockwise from the state of FIG. 2. It is sectional drawing which follows the ab line | wire of FIG. It is a side view which shows the state which the antenna surface of the RFID tag became parallel with respect to the radiation direction of a direct wave, and the radiation direction of a reflected wave. It is sectional drawing shown to the ab line | wire of FIG. FIG. 7 is a side view showing a state in which the RFID tag is rotated 90 degrees clockwise from FIG. 6. It is sectional drawing which follows the ab line | wire of FIG. FIG. 5 is a diagram illustrating a reception effective area or a reception effective length of each antenna in the state of FIG. 2 and FIG. 4. FIG. 9 is a diagram illustrating a reception effective area or a reception effective length of each antenna in the states of FIGS. 6 and 8. It is a block diagram which shows the radio | wireless communications system which concerns on Embodiment 2 of this invention. It is a side view which shows the radio | wireless communications system which concerns on Embodiment 3 of this invention. It is a block diagram which shows the radio | wireless communications system which concerns on Embodiment 4 of this invention.

Explanation of symbols

1 Reader / Writer 2 Main Antenna 3 RFID Tag (Wireless IC Chip)
4 Reflecting plate 4a Reflecting surface 8 Control unit

Claims (10)

A main antenna that radiates electromagnetic waves toward the wireless IC chip;
A reflector that reflects the electromagnetic wave from the main antenna toward the wireless IC chip;
A control unit for supporting the wireless IC chip;
The control unit has a function of causing a difference between received electromagnetic wave levels of a direct wave from the main antenna and a reflected wave from the reflector received by the antenna of the wireless chip. .   The control unit controls the effective reception length of the antenna of the wireless IC chip with respect to the electromagnetic wave, thereby receiving the received electromagnetic wave of the direct wave from the antenna and the reflected wave from the reflector received by the antenna of the wireless chip. The wireless communication system according to claim 1, wherein a level difference is generated.   The control unit controls the effective reception area of the antenna of the wireless IC chip with respect to the electromagnetic wave, thereby receiving the direct wave from the antenna and the reflected wave from the reflector received by the antenna of the wireless chip. The wireless communication system according to claim 1, wherein a level difference is generated.   The control unit supports a wireless IC chip having different types of antennas mixedly, and controls the wireless reception effective length and reception effective area for electromagnetic waves according to the type of antenna of the wireless IC chip. 2. The wireless communication system according to claim 1, wherein a difference is generated between the reception electromagnetic wave levels of the direct wave received from the main antenna and the reflected wave from the reflection plate received by the antenna of the chip.   2. The radio according to claim 1, wherein the control unit generates a difference in the received electromagnetic wave level by angularly rotating the radio IC chip within a reception area of the direct wave and the reflected wave. Communications system.   The wireless communication system according to claim 1, wherein the main antenna radiates circularly polarized electromagnetic waves. An electromagnetic radiation step that forms an electromagnetic wave path to the wireless IC chip of the electromagnetic wave radiated from the main antenna and the electromagnetic wave reflected by the reflector;
Level control step for causing a difference between the received electromagnetic wave level of the direct wave from the main antenna received by the antenna of the wireless chip and the reflected wave from the reflector in the reception area of the direct wave and the reflected wave of the electromagnetic wave And a wireless communication method.   In the level control step, the received electromagnetic wave level of the direct wave from the antenna and the reflected wave from the reflector received by the antenna of the wireless chip is controlled by controlling the effective reception length of the antenna of the wireless IC chip with respect to the electromagnetic wave. The wireless communication method according to claim 7, wherein a difference is caused between the two.   In the level control step, by controlling an effective reception area for the electromagnetic wave of the antenna of the wireless IC chip, the received electromagnetic wave level of the direct wave from the antenna and the reflected wave from the reflector received by the antenna of the wireless chip. The wireless communication method according to claim 7, wherein a difference is caused between the two.   In the level control step, the direct wave from the antenna received by the antenna of the wireless chip and the reflector are controlled by controlling the effective reception length and effective reception area for the electromagnetic wave according to the type of antenna of the wireless IC chip. The wireless communication method according to claim 7, wherein a difference is caused in the received electromagnetic wave level of the reflected wave from the radio wave.

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